Modulation of striatal dopamine metabolism by the activity of dorsal raphe serotonergic afferences.

Serotonin (5-HT)-dopamine (DA) interaction was studied in the caudate nucleus after electrical stimulation of the dorsal raphe (DR), an area containing 5-HT cell bodies and sending afferences to nigrostriatal dopaminergic neurons. The DR was stimulated by means of a bipolar stainless steel electrode for 16 min (10 Hz, 0.6 ms, 200 microA). 5-HT and DA metabolism were monitored before, during and after stimulation by in vivo differential pulse voltammetry. This electrochemical technique uses carbon fiber electrodes implanted in brain areas to record oxidation peaks corresponding to extracellular 5-hydroxyindolacetic acid (5-HIAA) and dihydroxyphenylacetic acid (DOPAC). Changes in the concentrations of the metabolites were recorded every 2 min in freely moving rats. Both 5-HIAA and DOPAC increased in the first minutes after the beginning of stimulation, the rise lasting 30 min after the end. That DR was closely involved was borne out by the fact that stimulation in the surrounding areas had no effect on either metabolite. Classical biochemical determinations in tissue samples were also used to study the effect on DA release: 3-methoxytyramine (3-MT) levels, measured in basal conditions and after blockade of its degradation by pargyline, were not changed, indicating that DR stimulation, though increasing DA metabolism, does not affect release. However, modulation of DA transmission by 5-HT afferences seems possible in certain circumstances. This 5-HT-DA interaction appears to be presynaptic (on dopaminergic terminals or cell bodies) since it is not prevented by kainic acid degeneration of striatal neurons.

Functional meaning of tryptophan-induced increase of 5-HT metabolism as clarified by in vivo voltammetry.

Differential pulse voltammetry with carbon fiber electrodes was used to study serotonin (5-HT) metabolism in freely moving rats. The electrodes implanted in the striatum recorded the extracellular 5-hydroxyindoleacetic acid (5-HIAA) oxidation peak after oral tryptophan (150 mg/kg). This 5-HT precursor did not modify the 5-HIAA peak in any rat tested, but it raised 5-HIAA levels determined in total tissue by a classical biochemical method (HPLC). The administration of 5-hydroxytryptophan (5-HTP) (25 mg/kg i.p.) induced an increase of 5-HIAA detectable both in the extracellular medium by voltammetry and in tissue samples. As previously shown, dorsal raphe electrical stimulation raises extracellular 5-HIAA in the striatum and this effect is enhanced by pretreatment with tryptophan. The results suggest that tryptophan in 'normal' conditions enhances 5-HT metabolism without affecting 5-HT release unless such release is stimulated. 5-HTP increases 5-HT metabolism and release.

Differences in the effect of the antidepressant amineptine on striatal and limbic DOPAC measured by HPLC-ECD and in vivo voltammetry.

The acute effect of the antidepressant amineptine was studied in two dopaminergic areas, the striatum and the limbic system, by in vivo voltammetry. This electrochemical technique uses carbon fibre electrodes implanted in brain areas of non-anaesthetized freely moving rats to measure DOPAC diffusing from the neurons. In vivo voltammetry recordings showed that amineptine induced a slight and transient decrease in DOPAC levels in the caudate nucleus but a persistent, clear-cut decrease in the nucleus accumbens. These results were confirmed by classical biochemical determination in tissue samples. The findings indicate the possible importance of the limbic area in the mechanism of action of amineptine.

Cross tolerance between ketamine and morphine to some pharmacological and biochemical effects.

Whether morphine and ketamine induced cross-tolerance to some of their common pharmacological and biochemical effects, namely analgesia and enhancement of metabolites of dopamine (DA) in the striatum and limbic area of the rat was analysed. Ketamine was given at the dose of 100 mg/kg, twice a day for 8 days. After this treatment, a challenge dose of morphine (15 mg/kg, i.p.) still induced analgesia comparable to that induced by morphine alone, showing no cross-tolerance to this effect. In contrast, the challenge dose of morphine given to ketamine-tolerant rats no longer enhanced metabolism of DA, indicating the appearance of cross-tolerance to this effect. A high degree of tolerance to morphine was obtained after the subcutaneous implantation of rats with pellets of morphine; a challenge dose of ketamine to morphine-tolerant rats induced marked analgesia, with no cross-tolerance to this pharmacological effect, while cross-tolerance was present to the biochemical effect. The existence of a high degree of reciprocal cross-tolerance in both areas and on both metabolites of DA is consistent with the hypothesis of action at a common receptor; the lack of cross-tolerance to the analgesic effect indicates that analgesia is achieved by a different mechanism for the two drugs.